SU736375A1 - Static switch - Google Patents

Description

one

The invention relates to electrical engineering, in particular to the technique of sparkless switching of alternating current circuits using power thyristors, and can be used in power supply systems.

A thyristor switch with automatic control of thyristor health is used, which is used for switching electrical loads in AC networks. The disadvantage of this switch is its low speed.

Of the known thyristor switches with automatic thyristor health monitoring, the closest to the technical essence and the achieved result of this invention is a switch 2 containing three pairs of anti-parallel thyristors connected, through which a three-phase load is connected in a three-phase AC voltage network, a control pulse generator thyristors, and a conductivity sensor. The latter contains a signal relay connected between artificial zeroes formed by two groups of resistors, which are connected to the phase conductors on the load and supply side and are connected in star.

Claims (2)

In the working state of the switch, the potentials of artificial zeros are different. Due to voltage skewing on the standpoint of the load of one of the thyristors, when the thread is broken, the balance is disturbed and electric current flows through the signal relay to the winding of the signal relay, causing the latter to operate. The alarm relay is activated: it switches on a sound or a light signal, at that the load is disconnected manually. From the moment the thyristor went out of service until the load was disconnected, the electrical receivers connected 20/1 to the faulty switch phase are supplied with a constant pulsating current, which is unacceptable. for electric motors, transformers n 7 tons, and, therefore, limits the range of the specified device. In addition, a thyristor switch using a similar sensor to conduct, the bridge is inoperable in the case of two-way power and load. The goal of the invention is to increase the speed of operation and enhance the functionality of the driver. This is ensured by the fact that the static switch contains antiparallel pairs: The bridged thyristors, in parallel with which are connected the thyristor state sensor inputs, and the thyristor control pulse driver, is equipped with TVipHCTopHHx pairs, a high frequency oscillator voltage, isolation transformer, element I. The T15ristors state sensors are made in the form of two-half "period transistor switches, the outputs of which through the element I are connected to the input of the pulse shaper control laziness inputs via measuring tran- sformatory, capacitors and secondary windings of razdelitelno- transformer whose primary is connected to a high frequency generator rectangular pulse voltage Iodko Gochen corresponds to the parallel thyristor pairs. FIG. 1 shows the scheme of the proposed device; in FIG. 2. time diagrams of us. The switch contains three pairs of thyristors 1 parallel-connected in parallel, to each pair of which a circuit is formed, which is formed by separation capacitor 2, the secondary winding of the isolation transformer. 3, the primary of which is connected to the high-frequency generator (5ru 4 rectangular voltage and the primary winding of the measuring transformer 5, the secondary winding of which is connected to the input of the full-wave transistor switch 6. The inputs of the keys through the matching device 7 are fed to the driver of the driver 8 control pulses. A transformer 9 is connected to the output of the imaging unit 8, the six secondary windings of which are connected to the thyristor control circuits 1. Throttle 10 is connected to each thyristor pair and councils of tim circuit is effected supply unit connected to the phase conductors of the network side {Fig. 1, not shown). 54 With the load on, the high-frequency generator 4 on the secondary windings of the transformer 3 induces an emf. During the conduction period of the thyristor pairs under the action of these EMFs in the circuits formed in each phase by the corresponding secondary windings of the transformer 3, the primary windings of the transformers 5, the wire thyristors 1 and separation capacitors 2 circulate the high-frequency currents, in turn, causing at the inputs of the corresponding prick 6 signals. These signals support the outputs of the keys 6 and, consequently, the corresponding inputs of the coincidence circuit 7 negative potential). At the moment of natural switching of the next thyristor, the high-frequency circuit is disturbed and the high-frequency signal at the input of the corresponding key disappears, which leads to the formation of a positive edge at eix) tension The positive voltage front through the coincidence circuit 7 is fed to the input of the driver control generator 8, causing the latter to fail and the current pulse to appear in the transformer 9, which unlocks the next order thyristor and, at the same time, restores the indicated circuit. at the appropriate input. A coincidence circuit appears zero potential, prohibiting the passage to the input of the signal conditioner from the two other keys 6, which leads to an automatic load shedding. The chokes 10 prevent the switch from malfunctioning, preventing the high-frequency currents from closing through the load or the mains supply. In the operating state of the switch, the load is connected to the network by simultaneously supplying control pulses to all thyristors, disconnecting by applying to the auxiliary input a matching circuit of zero potential from the power supply. As a result of preliminary testing of a full-scale switch sample, timing diagrams are obtained, represented in FIG. 2. Curves 11, 12, and 13 1 illustrate the change in time of the currents in the phases of pinching; curve 14 - the change in time of the signal at the input of the full-wave transistor switch 6 in phase C; IS ™ curve is the time variation of the output signal of the coincidence circuit 7; curve 16 is the time variation of the signal at the output of the driver 8 for the control pulses. At time tj in phase C, a single thyristor is out of order. The proposed static switch reliably protects power consumers from emergency operation, and the power supply network from undesirable distortion of the voltage shape, which greatly expands its scope and improves the reliability and quality of the power supply. Claims of the invention: A static switch containing pairs of anti-parallel-connected tristors, in parallel with which are connected the inputs of the thyristor state sensors, and the thyristor control pulse shaper, which, in order to increase the speed of operation and expand its functional capabilities, it is equipped with throttles by the number of Tfistor pairs, a high-frequency square-wave generator, a switching transceiver {element, element I, and the thyristor state sensors are made in the form of two switches Periodic transistor switches, the outputs of which are connected via the AND element to the input of the control pulse shaper, the inputs through the measuring transformers, separation capacitors and secondary windings of the split transformer, which are connected to the high frequency 1 side of the rectangular voltage pulses, are connected parallel to the corresponding T1fistorial .param. Sources of information taken into account in the examination 1. US Pat. No. 3665193, cl. 323-24, 1975. 2. The patent of England No. 1348494, 1Ш. H 2 K, 1975. Llulu t -